Unusual formation of hollow NiCoO2 sub-microspheres by oxygen functional group dominated thermally induced mass relocation towards efficient lithium storage

Hollow architectures have attracted tremendous interest for electrochemical energy storage applications thanks to their fascinating physicochemical merits. The purposeful exploration of efficient methodologies for fabricating hollow multi-composition oxide structures is an everlasting topic for electrochemists and materials scientists. In this contribution, we first devised a novel oxygen functional group dominated thermally induced mass relocation synthesis of binary NiCoO2 hollow sub-microspheres (NCOHSs). The requisite role of partial removal of oxygen-enriched organic species in the NiCo-glycerate precursor was rationally put forward for smart synthesis of phase-pure NCOHSs. By virtue of their compositional and structural advantages, the resultant NCOHSs exhibited superior high-rate lithium storage performance, when utilized as a competitive anode for Li-ion batteries (LIBs). Encouragingly, a large reversible capacity of similar to 805.9 mA h g(-1) was retained by the NCOHSs after 750 cycles at 500 mA g(-1), and even similar to 492.4 mA h g(-1) at a high current rate of 2 A g(-1). Furthermore, the NCOHS-based full device delivered an energy density of similar to 204.6 W h kg(-1), highlighting its appealing application in advanced LIBs. More significantly, we strongly envision that the unusual hollow formation mechanism proposed here will hold huge promise in enriching synthetic strategies of hollow binary metal oxide architectures for energy-related applications.